Paleontologists led by the University of Chicago’s Paul Sereno, a National Geographic Explorer-in-Residence, will publish their discovery Sept. 30 in the online journal Public Library of Science ONE. Joining Sereno to announce the discovery at a news conference in Mendoza, Argentina, today were Ricardo Martínez and Oscar Alcober, both of the Universidad Nacional de San Juan, Argentina.

“Among land animals, birds have a unique way of breathing. The lungs actually don’t expand,” Sereno said. Instead, birds have developed a system of bellows, or air sacs, which help pump air through the lungs. It’s the reason birds can fly higher and faster than bats, which, like all mammals, expand their lungs in a less efficient breathing process.

Discovered by Sereno and his colleagues in 1996, the new dinosaur is named Aerosteon riocoloradensis (“air bones from the Rio Colorado”). Aerosteon, found in rocks dating to the Cretaceous period about 85 million years old, represents a lineage surviving in isolation in South America. Its closest cousin in North American, Allosaurus, had gone extinct millions of years earlier and was replaced by tyrannosaurs.

“This dinosaur, unlike any other, provides more direct evidence of the bellows involved in bird breathing,” Martínez said. Its bones have telltale pockets and a sponge-like texture called “pneumatization,” in which air sacs from the lung invade bone. Air-filled bones are the hallmark of the bellows system of breathing in birds.

Alcober noted, “Despite its huge body size and lack of a breastbone or birdlike ribcage, this meat-eater had lungs that already functioned quite a bit like a bird’s.”

Aerosteon provided the evidence needed to seal the connection with birds — hollow bones in front and behind the ribcage, such as the wishbone (furcula) and the main hip bone (ilium).

Said co-author of the PLoS ONE article Jeffrey Wilson of the University of Michigan, “The ancient history of features like air sacs is full of surprising turns, the explanations for which must account for their presence in a huge predator like Aerosteon as well as in a chicken.”

Sereno further noted that Aerosteon has air sacs in an unusual place. “They come around the edge of the body and go into belly ribs. It looks like the beast had a system of air tubes under its skin,” he said.

The team highlighted three explanations for the evolution of air sacs in dinosaurs in their paper: development of a more efficient lung; reduction of upper body mass in tipsy two-legged runners; and release of excess body heat.

Sereno is especially intrigued by heat loss, given that Aerosteon was likely a high-energy predator with feathers but without sweat glands as in birds. Weighing as much as an elephant, Aerosteon might well have used an air system under the skin to rid itself of unwanted heat.

Also contributing to the PLoS ONE article were David Varricchio, Montana State University, and Hans Larsson, McGill University. The article can be viewed at http://dx.plos.org/10.1371/journal.pone.0003303.

The expedition that led to the dinosaur discovery was supported by the National Geographic Society and The David and Lucile Packard Foundation.